FI81227C - DATORNAETSYSTEM JAEMTE ANVAENDNING DAERAV FOER OEVERFOERING AV INFORMATION. - Google Patents

Description

1 81227

Computer network system and its use in the transfer of an information unit

The present invention relates to a computer network-5 system in which a plurality of user stations or terminals are connected to one or more host processors by means of a communication network.

An overview of the architecture used in computer networks is given in S. Wecker, "Computer 10 network architectures", Computer, September 1979. Another similar overview of Systems Network Architecture (SNA) is given in PE Green, "An introduction to network architectures and Protocols". , IBM Systems Journal, vol 18, no. 2, 1979. These publications describe several available computer networks, such as SNA, DNA, ARPANET networks, etc., by means of hierarchical architectural layers, the lowest layer being connected to the physical communication lines connecting several user nodes of the network and the highest 20 the level itself involves the conversation between several basic users of the network.

Computer network systems have been the subject of standardization work by the International Organization for Standardization (ISO) and in Herbert Zimmerman, "OSI 25 Reference Model - The ISO Model of Architecture for Open-Systems Interconnection", IEEE Transactions on Communications, April 1980, contains seven layers of architecture: physical, data link, network, transfer, session, presentation, and application layer. The present invention 30 is primarily directed to a session layer comprising establishing, terminating, and controlling a session between two basic users of a network.

In IBM's SNA (Systems Network Architecture) network (IBM is a registered trademark), several 35 pieces of information are recycled online between pairs of end users, with sessions established between those pairs.

2 81227 These information units are of several different types and hierarchical levels according to the number of layers they represent. A description of these information units and their use in established sessions is given in James D. Atchins, "Path Control: The Transport Network of SNA", IEEE Transactions on Communications, April 1980.

The expanded growth and use of data transmission networks in today's society has opened up numerous new possibilities in modern telecommunications technology.

There are many more parties in data transmission networks that are able to communicate with each other than in networks based on leased lines.

15 There are also many applications that require data communication link between the two sides only a short period of time, such as, for example, palkkavaraus- and bank-toimintasovellutuksissa.

These applications would require a lot of data-20 machine resources to establish a computer session between individual pairs for communication between them. The Nordic Public Data Network, presented in "The Public Data Networks in the Nordic Countries", published by the Swedish PTT in March 1978, is an example of a computer network using connected lines (circuit switching).

The object of the invention according to the present claims is to overcome these disadvantages of known computer network systems.

According to a preferred embodiment of the present invention, a plurality of independent terminals are grouped into a single unit, which is maintained by the host computer and which it defines in the network as a virtual terminal unit. Several 35 similar or different sessions are defined and established between applications on the host computer and

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3 81227 at the terminal.

These sessions are common to all physical terminals in the group.

According to another embodiment 5 of the present invention, a session established between a basic user on one node of a computer network and an application program on the host processor is registered as a shared session that can be shared by another basic user on another node without a new session establishment procedure.

According to yet another embodiment of the present invention, one or more sessions between the host processor application program and the terminals are provided on the ports of the host processor of the communication network for distribution to terminals operating in the network as secondary port stations.

An advantage of the invention is that the time and resources consuming procedures for establishing a session on a computer network are reduced.

Another advantage of the invention is that the response time of the terminal for calling a computer application program is reduced.

The present invention is particularly advantageous in applications where large numbers of short event-type messages are circulated in a computer network between end users and where the session set-up time is significant compared to the total session processing time.

The invention is described in the following environment, which is essentially based on IBM's SNA architecture, however, the invention is not limited to any particular type of network. A typical SNA network is described in the IBM manual "Advanced Communication Functions for Virtual Telecommunications-30 cations Access Method", GC27-0463-2, February 1981.

A detailed description of the invention is set forth below with reference to the accompanying drawings, in which:

Figure 1 shows a block diagram of a computer network system 35 according to the present invention.

Figure 2 shows 4,81227 architectural layers according to the present invention.

Figure 3 shows the basic link information unit.

Figure 4 shows a first example of a transfer header.

5 Figure 5 shows another example of a transfer header.

Figure 6 shows a block diagram of a computer network with connected lines.

Figure 7 shows a flow chart of the session establishment sequence for connected lines.

Figure 8 shows another embodiment of a data machine network with connected lines.

Figure 9 shows a flow chart of the operation of the network of Figure 8.

Figure 1 shows a computer network comprising 15 host processors 1 in target area A and host processor 9 in target area B.

The communication link control unit 2 is connected to the host 1 via the channel 16 and the local cluster control unit 4 is connected along the channel 15 to the host. The data-20 traffic connection control unit 2 is connected to the remote cluster control unit 5 via SDLC link 21 (Synchronous data link control). The communication connection control unit 2 is also connected via a link 25 to the remote communication connection control unit 6 and via links 22-24 to terminals 25 31-33 forming a terminal group 3. A link 26 crossing the destination area connects the communication connection control unit 2 to the remote a control unit 10 connected between the host process 30 Soror 9 and the remote communication control unit 11.

The host processor 1 includes an operating system 17, a plurality of application programs 13, and a virtual telecommunication access method 35 (VTAM), which comprises a system service control point (SSCP) component 14.

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Each element in the network of Figure 1 that can send or receive data is assigned a network address and is known as a network addressable unit (NAU). The network address 5 uniquely identifies an element regardless of whether the element is a device, such as a terminal or terminal control unit, a program such as an application program in a cluster control unit or a host processor, or part of a paging method such as VTAM. The network address contains the information necessary to route the data 10 to its destination. Three types of addressable units in the network have been defined: system auxiliary control point (SSCP), physical units (PU) and logical units (LU).

The system auxiliary control point (SSCP) 14 in host 1 of the host process-15 is the network-controlling VTAM component. The SSCP performs tasks such as opening and closing the network, assisting in establishing and terminating the connection between the addressable units of the network, and responding to network problems such as a link or control unit failure. To perform these functions, the SSCP must be able to communicate with the physical units and logical units under the network and under its control.

The physical unit (PU) is shown in Figure 1 by the circular notation PU. It is the part of the device, usually a program or circuit, or both, that performs the control functions of the device in which it is located and, in some cases, also of other devices connected to the device containing the PU. With respect to the devices under its control, the physical unit 30 operates during activation and deactivation, during fault recovery and resynchronization, during testing, and during the collection of hardware activity statistics. Every device on the network is associated with a physical unit. The local cluster control unit 4 35 has a physical unit 41 and the remote cluster controller has a physical unit 51. There are also physical units in the local communication connection control unit 2 and the remote communication control unit 6.

A logical unit is a device or program by which a basic user, a terminal user or a transmission mechanism 5 achieves access to a network. A logical unit can be built-in logic or a program associated with a terminal subsystem or a stand-alone device or application program. The logical unit for the network is the source of the query coming to the network. But the logical unit either has or does not have 10 original source. The content of the information query on which the query is based may come from a device controlled by a logical unit. Similarly, the network considers the logical unit as the destination of the query unit (RU).

In Figure 1, the logical unit is indicated by a circled 15 notation LU. The host processor 1 shows several logic units 13 of the application program. The local cluster control unit 4 has two logic units 42 and 43 which control the devices 44 and 45. The cluster control unit 4 has logic units 52-54 which control the device loops 55-57. . The conventional terminal group 3 has physical units and logical units for each terminal. Physical units are denoted by 34-36 and logical units by 37-39.

The purpose of the network according to Figure 1 is to establish and control a communication connection between two logical units in the network and the corresponding basic users. For example, the communication connection in question can be established up to the link 23 between the terminal 32, the communication connection control unit 2, the channel 16 and the VTAMt 12 in the host processor 1 and the application program 13.

Before further describing the operation of Figure 1, reference is made to the architectural layers shown in Figure 2. The figure shows its seven-layer structure according to Herbert Zimmermann's "OSI Reference Model", the highest layer being the application layer 71, followed by the presentation layer 72, the session layer 73, the transfer layer 74,

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7 81227 is a network layer 75, a data link layer 76 and a physical layer 77. This layered structure 70 represents one party of two communication connection parties that are in communication over a network. The structure 80, which includes the corresponding layers 81-87, represents the other party of the communication connection. Corresponding layers, such as presentation layer 72 and presentation layer 82, can be considered to be in communication via the Peer-to-Peer layer 62, via the Peer-to-Peer layer 62. Accordingly, the data link-10 layer 76 may be considered to be in communication with the data link layer 86 via the second link 66 between the partners.

The purpose of the multiple layers can be roughly explained as follows. The application layer is related to the conversation between two basic 15 users per se. The presentation layer determines the type of presentation of the data for that conversation, such as screen presentation, printing, etc. The session layer is related to setting up and directing a session between two basic users for the purpose of a conversation. The transport layer 20 provides control from the user node to the user node over the network, while the network layer defines control between two adjacent nodes in the network. The data link layer relates to the practice used to transfer data along a link between two nodes, while the physical layer addresses the electrical characteristics and signaling required for the connection.

The present invention is primarily directed to session layers 73 and 83 and practices between their partners. According to the present invention, session division 30 is used to reduce paging and response time in the network. When the network is operating in session division mode, the session layer 73 is divided into a higher shared session layer 78 and a lower base session layer 79.

The network in Figure 1 is related to the System Network Archi-35 tecture (SNA), while the layered structure of the image is related to the ISO model. The SNA architecture has only the following 8 81227 six layers: basic user, presentation, transmission and data flow, route, data link, and physical. The functions of the session layer of the ISO model have been added partly to the transmission and data flow layer of the SNA architecture and partly to the route control layer.

5 The data flow between several nodes in the network of Figure 1 consists of several information units shown in Figure 3. The interrogation response unit (RU) 94 and the interrogation response header (RH) 93 comprise a basic information unit (BIU) running in the network from one basic user node to another basic user node. The transfer header (TH) 92 is titled in front of the BIU to control the unit over the network. The transmission header includes address information to control the transmission of other necessary information. The interrogation response unit RU with a query response header with a header (RH) and a transmission start-15 tag (TH) is called a route information unit (PIU) 96. When this information unit is transmitted over the network from one node over a data link to another node, a link header 91 (LH) is added. unit and the link end tag (LT) 95 to the end of unit 20. This forms a basic link unit (BLU) as shown in Figure 3. The basic link unit comprises one or more PIUs.

Before the two target areas A and B of the network of Figure 1 can be used, the operator 25 of the host processor 1 must start the VTAM 12 of the target area A and the operator of the host processor 9 must start the corresponding paging method of the target area B. This operator-initiated start of the target area activates one or all of the sources in the target area. This means that sessions are established between the SSCP 14 in the target area 30 and the multiple PUs and multiple LUs.

It is assumed that the basic user of the LU 52 in the control unit 5 of the cluster of Fig. 1 wants to be in communication with the application program 13, for example with the application program 13a in the host-35 processor 1. Before that communication connection can be established you must

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9 81227 establishes a session between the LU in the cluster control unit 5 and the LU 13a in the host processor 1. The establishment of the session is started by the LU 52 by sending a logo query link 21, communication link control unit 2 and 5 via channel 16 to the SSCP 14 in the host processor 1. This query contains node identification information and also a proposal of session parameters for communication. Session parameters allow the basic user of each session to know what the other basic user 10 is doing in different communication connection situations. Session parameters are bit settings that indicate the rules to be followed in a session in matters such as query and counter sequences, content separation, query concatenation, the use of square brackets, and the use of 15 characters for reversal. Host processor 1 may agree or it may change the proposed session parameters. The logo template table in VTAM 12 is used to check session parameters. The host processor 1 then sends a "binding" request from the VTAM 12 via channel 16, the communication link 20 to the control unit 2 and the link 21 to the LU 52 for the cluster control unit 5, thus establishing a session between the LU 52 and the LU 13a in the host processor. The session is now established and the two basic users of the LU can be in communication with 25 interrogation units of the type shown in Figure 3. Once the telecommunication connection is completed, the other telecommunication connection party terminates the session.

When the group 3 of terminals 31-33 frequently exchanges short events with application programs of the application program type 30 13a in the host processor, establishing and terminating an unproductive session between the terminal LUs and the application program LU significantly burdens the host processor 1. According to the present invention, this unproductive portion is greatly reduced when 35 assigns a group address to the terminal group 3. The VTAM 12 then considers the terminal group 3 as a single node, a pseudo-node of the network, and uses the group address to communicate with the terminals in the group.

The communication connection between the terminal group 3 and the application program 13a in the host processor 1 is initiated by a conventional session establishment procedure between one terminal in the group, for example terminal 31, and the application program 13a. Once the session is started, the communication control unit 2 stores both the group address of the group 3 and the terminal address of the terminal 31 and sends the group address 10 as the source address over channel 16 to the VTAM 12. Once the session is established between the terminal 31 and the application program 31 another terminal such as terminal 32 can join or share this session . The PIUs (Figure 3) 15 exchanged between the terminals in the group 3 and the application program 13a are routed to one buffer area for one session in the VTAMs. The PIUs received along the channel 16 from the VTAM 12 to the communication link control unit 2 include a group address transfer in the header 92 as shown in Figure 3, while the terminal address is added to the query unit 94. The data link control unit 2 then divides the information units according to the terminal addresses.

It is important that the session is established between the terminal group 3 and the application program 13a in the host processor 1 before the session sharing can be used. If one terminal 25, for example terminal 33, sends an interrogation unit at the time when the session is not opened, the VTAM 12 analyzes this interrogation unit and detects that no session has been opened. VTAM 12 then returns certain status indicators of the interrogation unit set, which tell the terminal 30 33 that the session has not been opened. Terminal 33 then initiates the session by sending a standard logo query, after which other terminals can share this new session.

Session sharing is possible between Group 3 terminals only as long as multiple terminals use the same session parameters for the road-35 communication connection. If one terminal or application wants to use other parameters of session 81227, a new session can be established. Since VTAM 12 only sees one terminal in group 3, this means that the old session must be terminated before a new session is established. The second terminal can then share the new session 5 by applying its telecommunication connection to the new session parameter conditions.

The session allocation procedure described above is unknown to VTAM 12 and is handled by the communication link control unit 2 at a lower level. According to another embodiment of the present invention, the session allocation is discussed at the VTAM level. As an example, it is assumed that the LU 52 in the cluster control unit has established a session with the application program 13a in the host processor 1. It is also assumed that the LU 61 connected to the remote communication control unit 6 15 tends to join this session at the session division level. Data traffic between the host processor 1 and the LU 52 in the cluster control unit 5 flows along the link 21, the communication link control unit 2 and the channel 16. Data traffic between the LU 61 and the application-20 program in the host processor 1 flows through the remote control unit 6, the link 25, the communication connection control unit 2 and the channel 16. According to the SNA architecture, the transmission start name for the route information unit (PIU) of Figure 3 passing through the link 21 has the format FID 2 according to Figure 4. The transmission start name of the format FID 2 comprises a format identification field 101, a destination address field 102, a departure address field 103 and a sequence number field 104. The PIU running along link 25 and along channel 16 has the format FID 1 as shown in Figure 1. The initial label for the transfer of the format FID 1 30 includes a data count field 105.

The LU 61 is able to share the active session between the LU 52 in the cluster control unit 5 and the LUs 13a in the host processor 1 by modifying the header in Figure 4. The session identification field 106 is used for session 35 LU 52 to LU 13a and is added to the transfer header. This field contains a flag bit 107 which, when set to 12 81 227, indicates that the transfer header represents a divisible session information unit. The other bits in the SSID field 106 uniquely define and designate the session established between the LU 52 and the LU 13a. The VTAM 12 5 stores the session identification field 106 in the session identification table (138, Figure 6). When the LU 61 joins this previously established session, modified transmission initials of the type shown in Figure 4, i.e., FID IM, must be used in field 106 marked with the same bits as the established 10 main session between the LU 52 and the LU 13a.

When the VTAM 12 receives from the LU 61 that PIU, the destination address field 102 is the same as the main session initiated by the LU 52, i.e. the address of the application program LU 13a. However, the output field 103 is different in that it is the address of the LU 61. The VTAM 12 then examines field 106 and detects that the session divider bit 107 is set. It then compares this field 106 with the information stored in the session identification table and detects the corresponding session identifier at the session initiated by the LU 52. Thus, the interrogation unit sent with the 20 PIUs is taken to the same receiving buffer queue in the VTAMs as if it had been received from the source LU 52.

The present invention will now be described in more detail with reference to Figures 5, 6 and 7 in connection with a connected data network, such as a Nordic public data transmission network.

Figure 6 shows an terminal group 3 comprising terminals 31, 32 and 33, each connected to a respective port 171, 172 and 173. These ports are preferably 30 standardized X21 ports, according to the CCITT recommendation, which are connected via a connected data network 160. to other existing X21 ports 161, 162, and 163. The second terminal or terminals 175 and the corresponding port 174 represent other terminals in the network that do not belong to group 3. It is assumed that terminals 31-33 and 175 have automatic paging units. Terminals 31-33 and 175 ports

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13 81 227 171-174 represent the secondary side of the network, while the primary side is represented by ports 161-163 connected to the communication control unit 2.

A session may be established between the primary application program 13a of the secondary terminal 31 and 5 to exchange route information units (PIUs) between two basic users of that session. There is then a route between the terminal 31 and the application program 13a as follows: terminal 31, port 171, link 22, port 22, port 161, line 164, line 165 in the communication link control unit scanner 156, control unit buffer 155, control unit link control unit 154, control unit the route control unit 153, the switching point control unit 152 in the control unit, the channel 15 adapter 151, the channel 16 in the control unit, the buffer reserves 133 in the host processor 1, the interface 136 between the buffer reserves 133 and the application program 13a and the buffer 137 in the application program 13a.

The PIU 11a transmitted from the terminal 31 to the application program 13a has the transmission header 92 shown in Fig. 3 and the format shown in Fig. 5. This transmission header is of type FID 3 and includes a format identifier field 101 similar to field 101 in Figure 4. It also includes a local session identifier field 111 which uniquely identifies the terminal 31 to the communication control unit 2. According to the present invention, the conventional transmission method used in the SNA architecture the start tag FID 3 is modified by a field 112 comprising a shared session identifier field. This field contains a bit 30 set when using the shared session option. It also contains information about the main session that can be shared.

After the PIU transmitted from the terminal 31 has passed the link control unit in the control unit of the network 160, the scanner 156, the buffers 155 and the communication connections 35, it reaches the control unit 153 of the route control unit 153 and further the connection control unit of the communication connection control unit. The route control unit 153 changes the initial name of this PlUsn transmission from the modified format FID 3M shown in Fig. 5 to the modified for-5 country FID IM shown in Fig. 4, whereby the contents of field 112 in FID 3M are transferred to field 106 in FID IM. This new transfer start tag FID IM allows the VTAM to route the PIU from channel adapter 151 and channel 16 to the host processor.

This routing is performed by the transmission subsystem component 132 in the VTAM.

When VTAM 12 is initiated in a target area as in target area A of Figure 1, multiple sessions are established between the system auxiliary control point (SSCP) 14 and a plurality of PUs and LUs in the target area. These sessions are established using VTAM-15 queries such as "Activate PU" and "Activate LU".

The activated LU can then establish a session with the application program LU in the host processor, as described in connection with Figure 1. However, this does not apply to sources such as terminals connected via switched lines to the host processor. These terminals are not activated during the start of the target area. Starting a session along a connected line with the terminal and the host application program is therefore much more complex and time consuming than starting a session along fixed 25 leased lines.

Figure 7 shows a schematic diagram of the session establishment procedure used in the switched data network shown in Figure 6.

Operation begins when the network operator issues a "switch" command from the control terminal of the host processor 1. The "Swap" -30 command is handled by the SSCP component 131 in VTAM 12.

The SSCP 131 then sends an "activate link" (RU) request to the communication link control unit 2. The communication link control unit 2 responds to the "set response" RU to the SSCP 131. The SSCP then sends an "activate connection" -35 RU to the communication link control unit 2, corresponding to the "determine response" RU. Telecommunication connection control unit

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is 81227 2 is now ready to receive incoming calls from terminals over the network 160.

Assume that the terminal 31 in the group 3 of Figure 6 wants to establish a session with the application-program 13a in the host processor 1. It then uses its automatic calling unit to call one of the ports of the communication connection control unit 2, for example port 161. The connection link 22 is then established between the secondary port 171 of the terminal 31 and the primary port of the communication link control unit.

10 This incoming call is shown in Figures 6 and 7 from the physical unit 34 of the incoming terminal 34 to the communication connection control unit 2. The communication connection control unit 2 responds to the incoming call "station identification query" RU 11a "XID who are you?", Which is sent to the physical unit 34.

15 The physical unit 34 responds by sending its identification "XID response" to the communication control unit 2.

The conversation can now begin between the communication connection control unit 2 and the SSCP 131 in the host processor 1. The communication connection control unit 2 sends a "query-20 contact" which is an off-hook-RU of the SSCP. The SSCP responds to the "set control vector" RU in the communication link control unit 2. This RU determines certain conditions for establishing a session between the PU 34 and the SSCP 131. The communication control unit 2 responds with a predetermined response to the SSCP 131. The SSCP then sends a "contact" RU to the communication control unit 2. The communication control unit 2 responds with a second "specified response" followed by a "contacted" RU.

The SSCP now sends the "activate physical unit" RU 30 to the physical unit 34, which activates this unit. Physical unit 34 returns a "specified response" to SSCP 131.

The next SSCP 131 sends the "assign network address" RU to the communication connection control unit 2, which responds with a specified response. The SSCP then sends a "set control-35 vector" RU to the communication link control unit, which responds with a "specified response". This control vector is ie 81227 for the LU 37 at the terminal 31. The SSCP 131 continues to send the "activate logic unit" RU to the logic unit LU 37 at the terminal 31. This activates the logic unit at the terminal 31 corresponding to the "assigned response" RU: 11a 5 SSCP: lie. This completes the procedure by establishing a session system between the auxiliary control point 131 in the VTAM 12 and the physical unit 34 and a second session between the SSCP 131 and the logical unit 37 at the terminal 31. The session can now be established between the LU 37 and an application program such as host process 10 application program 13a, as if the terminal 31 were connected to the host processor via unconnected lines.

Logical unit 37 initiates the session by sending a "logo" RU to the SSCP 131. This logo query contains a set of 15 parameters that are proposed for use in the session to be established. The SSCP sends a "Control Initiate" request (Cinit, Control Initiate) to the application program 13a, which acts as the primary LU in the session. The primary LU 13a responds by issuing the macro instruction "OPNDST" to the SSCP 131. When the VTAM 12 executes 20 this macro instruction, the session parameters of the logo query are checked against the logo model table (LMT) 135 in the table area 134 in the VTAM 12 in Figure 6. Multiple control blocks 140, such as a Node Identification Control Block (NIB) 143, which identifies the secondary session, or LU, of the 25 sessions to be established. A session identification control block (SIB) 142 defining the current session is also established and an activity management control block (FMB) 141 for this session.

SSCP 131 sends a "binding" RU to the secondary logic-30 unit 37. This binding RU may contain the same session parameters as the original logo query, or it may contain session parameters that have been changed by VTAM 12. The secondary LU 37 then sends a response that accepts or rejects these session parameters. If the session parameters are accepted, the SSCP 131 sends a "start data traffic" RU to the secondary LU 37. The session is now established between the secondary LU 37, terminals 81227 and the primary LU 13a.

When the route control unit 153 of Fig. 6 receives a transmission FID 3 of the type FID 3 according to Fig. 5 from the terminal 31, it changes the transmission start label 5 to the format FID 1 according to Fig. 4, as previously described. This PIU is sent along channel 16 to the host processor 16 and the transmission subsystem component 132 routes it to a specific buffer area to the buffer reserves defined by the FMB block 141. The RU 94 of the PIU 96 (Figure 3) is then transferred from the VTAM buffer 133 to the application program buffer 137. Correspondingly, the PU is transferred from the application program buffer 137 to the VTAM buffer 133 assigned by the FMB block 141 and formed by the TSC component 132 to the PIU. by adding a transfer header 92. The TSC-15 component 132 then routes this PIU to the communication link control unit 2 and its access point management unit 152 and further to the route control unit 153. The route control unit 153 thus converts the FID 1 format to the FID 3 transmission header name to terminal 31.

The described session establishment procedure can be used to establish a session between the host application program and the terminal group in Figure 6. This means that when a session is established between the terminal 31 and the application program 25 13a, the content of the session sharing the sensor field 112 is stored in the modified transfer header FID 3M in Figure 5. , Session Sharing Control Table) 158 in the access point management unit 152 of the communication connection control unit 2. The second terminal 30 can then share this established session using the same SSID information 112 in its transmission initial name when sending the PIU to the application program 13a. This SSID information is compared with the data stored in the SSCT 158 to route the PIU to the same destination as for the main session 35. This session allocation is made at the level of the communication link control unit. The PIUs exchanged between the communication link control unit 81227 and the host processor 1 use the group address for the terminal group 3 in the original address field (Figure 4) of their transmission initials 92 (Figure 3).

5 When a station outside the group 3, such as terminal 175, shares an established session, the information for the main session in the transfer header field, e.g., application program 13a of terminal 31, must be stored in the session allocation table SST 138 in VTAMs 12. From session 10 shared from terminal 175 to application program 13a The PIU routes its destination to the buffer in the VTAM 12 by the transmission subcomponent 132 by comparing the SSID information in the PIU with the information stored in the table 138. If there is a listing input defining the main session, the RU portion of this PIU is queued at the VTAM buffer 133 previously assigned to the corresponding main session.

Figures 8 and 9 show another embodiment of the present invention.

As shown in Figure 8, the host processor 1 20 is connected via channel 16 to the communication connection control unit 2. Each of the plurality of terminals 281-284 is connected to a corresponding secondary port 271-274 in a connected data network 260, such as the Nordic Public Data Network. The plurality of primary ports 261-263 25 of the network 260 are connected to the primary ports 251-253 of the communication link control unit. Ports 261-263 are preferably standard X21 ports.

An example of a communication connection control unit 2 is an IBM type 3705 control unit, which is presented in the manual "IBM 3704 and 3705 Communications Controllers, Principle of operations", GC30-3004-6, October 1979.

An example of a terminal 281-284 is an IBM type 3275 terminal described in the IBM manual "An introduction to the IBM 3270 Information Display System", 35 GA27-2739-14, February 1982.

Assume that terminals 281-284 represent large

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19 81 227 sets of terminals used to communicate with the application program 213 in the host processor 1 on an event basis. Events sent over the network are fairly short messages, however, the frequency of occurrence of events is high. In a conventional data network, such event traffic requires a very large number of session set-ups and decommissions, resulting in a very high host processor load time compared to the useful transaction processing time. The solution to this traffic problem is a session sharing system according to the present invention.

Multiple parallel sessions 241-243 are established between the primary half-sessions (primary part of the session) 201-203 and the secondary half-sessions (secondary part of the session 15) 231-233 of the application program 213 for the ports 251-253 of the communication connection control unit. These sessions are allowed to be established by sessions 341-343 established between the System Services Control Point 294 (SSCP) on the host processor and the physical units 221-223 for ports 251-253 of the communication-20 connection control unit 2, and corresponding sessions is established between the SSCP 294 and the logical units 231-233 for these ports. Each half-session on the primary side for application program 213 25 includes a Node Identification Block (NIB) 291-293. The example of Figure 8 shows three parallel sessions 241-243 between the application program 213 and the three ports 251-253 in the communication connection control unit. It will, of course, be apparent to one skilled in the art that any number of parallel sessions and ports can be used.

An example of sessions established between the communication ports of the communication control unit and the host processor application program is described in the IBM Handbook "IBM X.25 NCP Packet Switching Interface" GC30-35 3080-1, July 1982.

Terminals 281-284 are considered as terminal group 203, where 20 81 227 all terminals are of the same type and use the same session parameters. Terminals 281-284 and their secondary ports 271-274 should be connected to primary ports 261-263 using the group dial number. This means that the terminal 281 for port 271 dials a group number to establish a connection to the primary port, which may result in a connection 276 between ports 271 and 262. If port 262 is occupied, for example, by connection 277, it may be possible to connect port 271 to port 261, which is connected along line 264 10 to port 251 of the communication connection control unit.

Data traffic between one terminal, for example terminal 281 in Figure 1, and the host processor 1 will now be described with reference to Figure 9. Assume that the terminal 281 calls the communication connection control unit 2 via the network 260 using the group dial number for ports 261 and 261-263 and that it succeeds in accessing the port 262 via the switching link 276. To this "incoming call" in Figure 9, the communication control unit responds with the station identification query XID "who are you". The terminal then responds with an "XID response" 20 that identifies its position address to the communication control unit and further to the application program 213 using the previously established session 242 between the application program 213 and the port 252 in the communication control unit 2. The host application 25 then sends a query "what can I do ", after which the terminal responds with" event query ID ". This transaction query contains identification information such as a password. The application program responds to the query by acknowledging or rejecting the transaction. When the acknowledgment is positive, data exchange between the terminal 281 and the application program 213 begins using the previously established session between the application program 213 and port 252, which session is shown as session 242 in Figure 8. When the event is completed, send the "end of event" terminal -35 message to the application program. 213, which corresponds to "acknowledgment". Terminal 281 disconnects circuit 276 after it is

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2i 81227 sent an "end of contact" request to the host application.

The data network system according to Figure 8 and Figure 9 can be used, for example, in banking applications.

The application program 213 in the host processor 1 is connected to the database and the terminals in the terminal group 203 are in communication with that database on an event basis via the application program 213.

When the network operator starts the network working day 10 in the morning, the host processor first establishes three parallel sessions 241-243 between the application program 213 and the ports 251-253 of the communication control unit. This means that the VTAM 12 in the host processor 12 considers the terminal group 203 as three physical units 221-223, 15 as three logical units 231-233 and three links 251-253 instead of one physical unit and one logical unit at each terminal 203. VTAM 12 also assigns network addresses in the communication link control unit 2 to these three physical and logical units 20.

It is to be understood that the system of Figure 8 and Figure 9 substantially reduces the load caused by establishing and terminating a session compared to conventional session maintenance for connected connections. It is to be understood that the physical units and 221-11 and 221-223 and the logic units 231-233 in the communication control unit are activated in the conventional manner when the network operator starts in the network host processor on the morning of 1 business day. This establishes sessions 341-343 between SSCP 30 294 and said physical and logical units. Parallel LU-LU sessions 241-243 may preferably be established on the primary side of the host processor. In that session establishment procedure, the session parameters are invalidable, as in the conventional system, and 35 standard "binding" queries are used to decide which session parameter should be used. It can therefore be said that 22 81 227 sessions 241-243 are not fixed, but can be adapted to the type required by the application for terminals in group 20. However, it is important that all three sessions use the same session parameters at the same time, because the terminals in group 203 are randomly connected to the three ports 261-263.

The duration T of a session, such as sessions 241-243, can be several hours. The session establishment time T1 is in the order of a few hundred milliseconds. The duration t of event 10 is preferably a few seconds, while the actual processing time t1 for the event in the host processor is only a few milliseconds. This means that t is at least an order of magnitude smaller than T and that t1 is at least an order of magnitude smaller than T1.

The present invention reduces the total response time when calling terminals, because the session establishment time T1 is not required in the processor 1 for each event.

The present invention is not limited to an SNA architecture having a precisely centralized control system that uses the system auxiliary control point 294. Control sessions 341-343 can thus be replaced by some other type of network control system. An essential inventive principle is that one or more shared sessions, preferably established in accordance with the session parameter rules to be invalidated, are used to serve multiple user stations or terminals.

The present invention is also not limited to the embodiment shown. It is within the scope of the invention, for example, to establish a plurality of parallel sessions 242-1, 242-2, 30 242-3 ... in Figure 8 between the primary LU202 and the torsion LU232 for port 252. These sessions can be set up using different session parameters, thus allowing different session parameters and user terminals to be connected to the same port. According to this modification, the calling terminals 281-284 should identify their session type, i.e. what parameters and which session is used for multiple sessions 242-1 ... 242-3

II

Of the 23 81 227, a session identifier field 111 or 112, Figure 5, should be used in its transfer initial name for each PIU. The essential inventive idea is that two or more users share one basic session.

It is also within the scope of the present invention to establish a plurality of parallel sessions between each primary port and a plurality of application programs, respectively. This means that all terminals 281-284 can use any 10 ports 261-263 to connect to any application program 13. This system is the most common form of session and port sharing in a data network.

In that system, for each application program 13 in the first set of application programs, 15 one session is established for each primary port of the second set of primary ports 251-253. Each of the third set of terminals of the secondary data terminals 281-284 is adapted to call any primary port to exchange an event with any application program. The network 260 connecting the secondary terminal ports 271-274 to the primary 20 ports 261-263 may be either a circuit switching network or a packet switching network. All that matters is that the information unit PIU accessing the primary port 261-263 from the secondary port 271-274 connected to the secondary terminal 281-284 has session identification information 25 112 or 106, Figures 4 and 5, communication control to allow the unit 2 to route that PIU to the selected session sessions from a plurality extending from that port to achieve the desired application program 13.

Examples of several types of session parameters used for multiple types of sessions are provided in the IBM System Network Architecture Reference Summary GA27-3136-4, January 1981.

Claims (18)

A method of transmitting information units in a computer network system, comprising establishing a first session between a first addressable node (13a) in a host computer (1) and a second addressable node (31) in a station connected to the network , which session establishment procedure includes defining a set of session parameters among a plurality of parameters to be used in the session, which parameters define the communication rules to be followed at both ends of the session, characterized by sharing the established first session. with a third addressable node (32), for exchanging information units (96) between the first node (13a) and the third node (32) without establishing a second session, and identifying to the system each information unit being transmitted or is received by the third node of the delegated session as an information unit relating to the established first session, which identification is provided by session identifier data in each transmitted information unit. Method according to claim 1, characterized in that the identification of an information unit is done by comparing session identifier data (106, 112) in a transmission lead (92) in the information unit with the system identifier data (138, 158) stored in the system. Method according to claim 1, characterized in that the identification of an information unit 30 is accomplished by means of session identifier data in the form of a group address in the original address field of the information unit (103). Method according to claim 1, characterized in that the identification of an information unit is accomplished by means of session identifier data in the form of an address (103) for an input / output (251-253) for a communication controller (2). 30 81 227 The method of claim 1 wherein the computer network (260) comprises a plurality of addressable primary ports (251-253, 261-263) connected to the host computer and a plurality of secondary ports (271-274) each connected to the host computer. a corresponding data terminal (281-284) and each of which is connectable via a connected network connection (276,277) to a primary port, characterized by the establishment of at least one session (242) between at least one primary port (252) and an addressable node (202, 213) ) in the host computer, preserving the established one session (242) between said one primary port (252) and the host node a time T, connecting a first secondary port (271) to said one primary port (252,262) via an connected connection (276) through a call from a corresponding terminal (281), initiation of a data conversation between said terminal (281) and the host node for a transaction using the previously established one session (242), breaking the line connection (276) and completing the transaction, the duration time t of the transaction being an order of magnitude less than the duration time T of said one session, and connecting another data terminal (283) via its secondary port (273) to said one primary port (252,262) prior to said one session is terminated in and for a new transaction, whereby a plurality of secondary terminals share a session (242). Method according to claim 5, characterized in that the primary IN / OUT threads (251-253) are located in a communication control unit. Method according to claim 6, characterized in that a plurality of sessions (242-1, 242-2, 242-3), each defined by a different set of session parameters, are established between a primary port ( 252) and an addressable node (213) in the host computer. Method according to claim 7, characterized in that a session identifier field (111,112 Fig. 5) in a transmission lead (92) of an incoming information port (96) for a primary port (252) is used to identify which session (242-2) among a plurality of parallel sessions (241-1,242-2,242-3) to use for a transaction. The method of claim 1 comprising transmitting information units between a first plurality of application programs (13,213) in the host computer and a second plurality of data terminals (281-284) via the data network (260) having a third plurality of primary ports (252-253). , 261-263) on the network host side (2) and secondary ports (271-274) connected to the terminals on the network terminal side (203), characterized by the establishment of parallel sessions between each application program (13,213) and all primary ports (251). -253) and providing session identifier information (106,111,112) in each information unit (96), which travels between an application program and a data terminal via said data network. Method according to claim 9, characterized in that the data network is a network with connected connections. 11. A method according to claim 1, characterized in that the data network is a network operating in a packet exchange mode. A computer network system for data communication between a plurality of addressable nodes, including a plurality of links connecting the nodes to at least one host computer (1) for establishing a session between a first (13a) and a second (31) node in the network. and for exchanging information units (94.96) between said both nodes according to session parameters defined during a session establishment operation, characterized by means (158, 138) for storing session identifier information and means (132,152) for comparing said stored session identifier information with a session identifier field (106,112) in an information unit (96) transmitted by a third node (32,61) to the first node (13a) without session establishment between the first node and the third node 32 81,227, whereby an established session between two nodes is shared by a third node. Network according to claim 12, characterized in that said session identifier storage means 5 comprises a shared-session table (158) housed in a communication controller (2) which connects the second and third nodes to the first node. which is in the host computer (1). Network according to claim 12, characterized in that said session identifier storage means comprises a split-session table (138) housed in a virtual transmission access method (12) in the host computer. 15. A network according to claim 12, characterized in that said session identifier field (106,112) is housed in a transmission lead (92) in an information unit (96) traveling through the network. Network according to claim 15, characterized in that said session identifier field comprises a session sharing mode indicator (107). 77. A network according to any of claims 12-16, characterized in that the first node is an application program (13a) in the host computer (1), the second and the third node are data terminals (31,32,175), which are connectable via connected wires (22, 23) to a communication controller (2) and further to the application program (13a) which uses a shared session. 18. A network according to claim 17, characterized in that an information unit (96) transmitted from a data terminal (31) to the communication controller 30 (2) comprises a first type of transmission lead containing a local session identifier field (111) and a shared-session identifier field (112), which transmission lead changes in the communication controller to a second type of transmission lead, comprising a source address (103) and a destination address (102), where the source address is the network address of a group (3) of session shareable data terminals (31-33). li